Solid‐State Photochromism of Chromenes: Enhanced Photocoloration and Observation of Unstable Colored Species at Low Temperatures

Harada, Jun; Ueki, Kiyomi; Anada, Masahide; Kawazoe, Yuta; Ogawa, K.

doi:10.1002/chem.201101717

Cited by 17 publications

(11 citation statements)

References 33 publications

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“…This type of thermochromism does not involve any changes in the molecular structure of the dye, in contrast to the thermochromic effects resulting from a shift in the chemical equilibrium associated with a change from a colored to a noncolored species due to changes in the temperature. − Thus, the thermochromism observed with the betaines has been called negative thermosolvatochromism, being due to an increase in the differential stabilization of the zwitterionic electronic ground state of the dye relative to its excited state with decreasing temperature. ,, The explanation for this is that both specific and nonspecific intermolecular interactions involving the molecules of dye and solvent are strengthened with a decrease in temperature, , leading to higher E T (30) values. In other words, a decrease in temperature of a solution improves the solvation capability of the solvent, demonstrating that solvent polarity is temperature-dependent .…”

Section: Thermosolvatochromism Of Pyridinium N-phenolate Dyesmentioning

confidence: 99%

PyridiniumN-Phenolate Betaine Dyes

2014

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Introduction 10429 2. Historical Contextualization 10431 3. Synthesis of Pyridinium N-Phenolate Dyes 10433 4. Solvatochromic Properties of Pyridinium N-Phenolate Dyes 10435 4.1. X-ray Crystallographic Studies of the Molecular Structures of Pyridinium N-Phenolate Dyes 10437 4.2. Quantum Chemical Calculations Involving Pyridinium N-Phenolate Dyes 10438 4.3. The E T (30) and E T N Solvent Polarity Scale 10440 4.4. Multiparametric Approaches to the Analysis of the E T (30) and E T N Scale 10441 5. Secondary Solvatochromic Pyridinium N-Phenolate Dyes 10442 6. Investigation of the Physical Properties of Room-Temperature Ionic Liquids 10443 7. Thermosolvatochromism of Pyridinium N-Phenolate Dyes 10450 8. Halochromism of Pyridinium N-Phenolate Dyes 10451 9. Piezosolvatochromism of Pyridinium N-Phenolate Dyes 10452 10. Pyridinium N-Phenolate Dyes in the Investigation of Solvent Mixtures 10453 11. Application of Pyridinium N-Phenolate Dyes in the Construction of Chromogenic Chemosensors 10455 11.1. Chirosolvatochromism of Pyridinium N-Phenolate Dyes 10456 11.2. Chromoionophores 10456 11.3. Chromogenic Chemosensors for Anionic Species 10457 11.4. Chromogenic Chemosensors for Neutral Analytes 10458 12. Pyridinium N-Phenolate Dyes as Probes To Measure the Polarity of Solid Surfaces 10459 13. Pyridinium N-Phenolate Dyes in the Study of Microheterogeneous Systems 10460 13.1. Investigation of Surfactants in Aqueous and Organic Media 10462 13.2. Pyridinium N-Phenolate Dyes in the Investigation of Cyclodextrins in Solution 10463 13.

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Section: Thermosolvatochromism Of Pyridinium N-phenolate Dyesmentioning

confidence: 99%

PyridiniumN-Phenolate Betaine Dyes

2014

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“…Mechanistic details of the photochromic properties of benzopyrans have been extensively investigated. ,− Needless to mention that the TC and TT isomeric forms of the o -quinonoid reactive intermediates shown in Figure are mainly responsible for the observed coloration attendant upon photoirradiation of benzopyrans. The TT isomer is generated by a two-photon absorption of the benzopyran through initial formation of the TC isomer such that the former is likely to be formed only minimally when the precursor benzopyran is subjected to photoirradiation for a shorter duration.…”

Section: Resultsmentioning

confidence: 99%

“…173 K) due to the extremely fast thermal reversion of the photogenerated o -quinonoid intermediate at room temperature . Thus, modulation of the spectrokinetic properties of o -quinonoid reactive intermediates and the associated photochromic phenomenon of diarylbenzopyrans have been a subject of extensive investigations. − …”

Section: Introductionmentioning

confidence: 99%

Contrasting Photochromic and Acidochromic Behaviors of Pyridyl- and Pyrimidylethynylated Mono- and Bis-Benzopyrans

et al. 2021

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Investigation of photochromic and acidochromic behaviors of a set of pyridyl- and pyrimidylethynylated mono- and bis-benzopyrans reveals an intriguing influence of the N-heteroaryl ring on spectrokinetic properties of the photogenerated o-quinonoid colored reactive intermediates. While the absorption maxima of the pyridylethynylated bis-benzopyran and its photogenerated o-quinonoid colored species undergo bathochromic shifts by ca. 40 and 22 nm, respectively, in the presence of an acid (e.g., trifluoroacetic acid (TFA)), the same remain unaffected for the analogous pyrimidylethynylated bis-benzopyran and its photogenerated o-quinonoid colored species under similar conditions. Modification of the photochromic behavior of these benzopyrans and, hence, spectrokinetic properties of their photogenerated o-quinonoid species in the presence of H+ is a consequence of relative proton affinities of N-heteroaryl rings, i.e., pyridyl/pyrimidyl, and the resonance effects relayed through the ethynyl spacers in a push–pull π-delocalized-type skeleton; the mesomeric effects operate in a contrasting manner depending on the N-heteroaryl ring in the absence and in the presence of an acid. These molecular systems offer a unique opportunity to modulate both photochromic and acidochromic properties of benzopyrans and their photogenerated colored o-quinonoid intermediates by leveraging N-heteroaromatic rings.

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“…9,10 This behaviour has also been observed for the reference molecule having this skeleton, 3,3diphenyl-3H-naphtho [2,1-b]pyran (herein named RN, Scheme 1), that was extensively reported in the literature, especially over the last three decades. 5,7,[11][12][13][14][15][16][17][18][19][20][21][22][23][24][25][26][27] The transformation of a benzo-or a naphthopyran into a photochromic system possessing only a T-Type or a P-Type behaviour might undoubtedly be of interest from both points of view of basic research and practical applications. This could be achieved by choosing a suitable solvent, the temperature range or introducing modifications of the molecular structure.…”

Section: Introductionmentioning

confidence: 99%